奥地利专利AT517407A1 Laser unit with collimator adjustment device

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专利摘要:
In a laser unit (11) for a vehicle headlight, the laser diode (12) is associated with an adjustable collimator optics (13) for the laser light emitted by the laser diode. The collimator optics (13) comprising at least one optical component, e.g. a lens (14), is arranged in the longitudinal direction (x) arranged in an adjustable by an adjustment device (20) distance from the laser diode (12). The adjusting device comprises a carrier (24), which is adjustable relative to the laser diode (12) by means of longitudinal adjusting means (21) along the longitudinal direction and in which the optical component (14) in a holder (23) pivotally mounted transversely to the longitudinal direction (x) is.
公开号:AT517407A1
申请号:T50517/2015
申请日:2015-06-19
公开日:2017-01-15
发明作者:Mayer Matthias
申请人:Zkw Group Gmbh；
IPC主号:

专利说明:

Laser unit with collimator adjustment device
The invention relates to a laser unit for a vehicle headlight with a laser light source, preferably a laser diode, a bearing housing in which the laser light source is mounted, and an adjustable collimator optics for laser light emitted by the laser light source, wherein the collimator optical system comprises at least one optical component in a along a Is arranged longitudinally extending distance to the laser light source.
As used herein, optical device means an optical component having light-gathering or scattering properties, and more specifically, a shape reflector (e.g., domed or domed mirror) or an optical lens, and combinations of these components may be included. The longitudinal direction is understood to mean the direction of the imaginary axis along which the light propagation of the laser light from the laser light source to the collimator optics takes place.
The use of laser light sources in motor vehicles, especially for headlights of motor vehicles, is currently gaining in importance, since laser diodes allow more flexible and efficient solutions, whereby the luminance of the light bundle and the light output can be increased considerably.
In the known solutions, however, the laser beam is not emitted directly from the lighting device or the headlight in order to avoid endangering the eyes of humans and other living beings by the extremely concentrated light beam of high power. Rather, the laser beam is directed to an intermediate conversion element containing a luminescent conversion material, called "phosphor" for short, which converts the laser light, for example a wavelength in the blue region, into visible light, preferably white light; In the context of the present invention, "phosphor" is understood in general to mean a substance or a substance mixture which converts light of one wavelength into light of another wavelength or of a wavelength mixture, in particular "white" light, which also can be subsumed under the term "wavelength conversion". In most cases, the conversion element is a programmed pivoted
Mirror upstream (with respect to the beam path of the laser light) through which the laser beam can be directed to different locations on the area conversion element. In order to achieve that on the conversion element well-defined light spots or (with a moving mirror) light pattern are generated, the light originating from the laser light source is collimated by means of an optical arrangement, which is referred to here as collimator optics. The collimator optics are typically located immediately after the laser light source (with respect to the beam path) and may include multiple optical components and / or light-limiting components, but is often formed by a single optical lens.
Due to production-related deviations of the relative position and orientation of the components of the collimator and laser light source, but also to possibly allow later readjustment, it is necessary to adjust the optical components of the collimator relative to the laser light source so that a light spot with the desired sharpness generated on the conversion element can be.
It is therefore an object of the invention to allow an accurate and at the same time uncomplicated adjustment of the collimator optics. It has been shown that it is advantageous to allow not only adjustment of the alignment, but also the distance of the optical component (s) of the collimator optics to the laser light source. In particular, in laser modules with multiple laser light sources, an individual adjustment of the individual laser beams is required.
This object is achieved according to the invention starting from a laser unit of the type mentioned by an adjusting device associated with the collimator optics with a carrier which is adjustable along the longitudinal direction relative to the laser light source, wherein the at least one optical component within the carrier at least one transverse to the longitudinal direction extending spatial axis is pivotally mounted.
This solution results in a simple and reliable adjustment possibility of the collimator optics both along the longitudinal direction and transversely thereto, which is also possible after the assembly of the optical system (laser light source, collimator optics, wide mirror, etc.). In this way it is possible to set the lighting technology extremely important, but very sensitive to deviations alignment of the collimator with respect to the laser light source and correct incorrect settings. So far, often expensive assembly cycles can therefore be avoided. Another advantage is the large adjustment range, which provides this technical solution.
In a favorable development of the invention, a longitudinal adjusting device adjustable along the longitudinal direction can be provided in the bearing housing, wherein the carrier is supported against the at least one longitudinal adjusting means. In this case, in one of the possible advantageous embodiments, the longitudinal adjusting device can be realized as a number of adjusting screws running parallel to the longitudinal direction. In order to keep a later misadjustment, the longitudinal adjusting device can additionally be fixed in its longitudinal position. In addition, it may be expedient if at least one elastically deformable spring element is provided in the bearing housing, with which the carrier is pressed against the at least one longitudinal adjusting means.
In many embodiments, a simplification of the construction of the laser unit can be achieved by the carrier in the bearing housing being adjustable along the longitudinal direction, whereas the laser light source is firmly positioned in the bearing housing.
In order to achieve a higher flexibility of the optical adjustment options, it may be favorable if the at least one optical component is pivotably mounted about two spatial axes, wherein the mutually perpendicular spatial axes are perpendicular to the longitudinal direction.
In an advantageous embodiment of the invention with regard to the realization of the pivoting of the collimator can be provided that in the carrier a holder in which the optical element is held, and at least one attacking on the bracket Hebei - preferably two - are provided, wherein on a outer end of the or each lever, a support means mounted in the support is provided, with which the Hebei is adjustable with respect to its pivot position.
It can also be provided that in each case an elastically deformable spring element between a Hebei and a counter surface of the carrier is arranged and the at least one Hebei is pressed by an adjusting means, preferably an eccentrically extending screw, via the spring element against the counter surface.
Furthermore, it can be provided that the Hebei is connected to the associated actuating means via a hinge connection, wherein the hinge connection between an end face of the actuating means and a touching contact surface of the lever is formed, wherein preferably the end face and / or the contact surface as a spherically curved contact surface are formed.
In order to prevent later deviations of an adjustment once reached, the or the adjusting means may additionally be fixed against rotation.
In addition, it can simplify the manufacture, when the holder and the at least one Hebei are integrally formed with each other.
The invention is particularly suitable for a laser module having a plurality of laser units of the type described above, as well as for a vehicle headlight, in particular for a motor vehicle, with a laser unit or a laser module as described above.
The invention together with further developments and advantages will be explained in more detail below with reference to an exemplary embodiment, which is illustrated in the drawings and relates to a laser unit with a laser diode in a laser module for a motor vehicle headlight. The drawings show in schematic form:
1 shows a view of a laser unit in a laser module according to the Ausführungsbei-game, with a view of the outside of the laser unit, over which the adjusting components are accessible.
Fig. 2 is a sectional view of the laser unit according to the section A-A of Fig. 1;
3 is a perspective view of the adjustment device of the laser unit;
FIG. 4 is a perspective view of the carrier in the adjustment device of FIG. 3 with a lens holder; FIG.
5 shows a variant of the lens holder; and
6 shows a headlight with the laser module of FIG. 1.
Referring to Figs. 1 and 2, a laser module 10 includes one or more laser units 11 each having a laser light source 12 formed as a laser diode in the user shown; however, other laser sources of known type are usable in a corresponding manner. The laser units 11 are lined up, for example, in the laser module 10 along a Abstrahllichtweges 19 side by side, in which the light emitted from the laser unit 11 by a belonging to her Abstrahlöffnung 15 light via a mirror 16 is coupled.
The laser light source 12 is associated with a collimator optics 13, which is realized in the illustrated exemplary embodiment by a single converging lens 14 (collimator lens) and is arranged in the beam path immediately after the light source 12. The beam path from the laser light source 12 to the collimator optical system 13 runs along the longitudinal direction x in the sense of the invention (vertical in FIG. 2). The emission opening 15 and the mirror 16 are in the embodiment also in the (extended) longitudinal direction x.
Fig. 1 shows the outside of the laser unit 11. In the middle of the laser unit 11, the laser diode 12 is inserted, wherein in the figure, the electrical Anschltisse the laser diode can be seen. On the outside, one or more heat sinks 17 may be applied; in the illustration of FIG. 1, the cooling fins of the heat sink 17 are shown shortened for the sake of clarity. The heat sink 17 has, in addition to an opening for the already mentioned electrical Anschltisse the laser diode 12 further openings through the adjusting components of the adjusting device according to the invention, namely the heads of adjusting screws 21, 31, 41 are accessible from the outside in the illustrated embodiment. In addition, first fastening screws 45, with which the laser unit 11 is mounted in the housing of the laser module 10, and second fastening screws 18 for fixing the heat sink 17 can be seen.
FIG. 2 shows the adjustment device 20 according to the invention for the collimator optics 13 in a longitudinal sectional view of the laser unit 11. The laser unit 11 comprises in particular a lens holder 23 which holds the lens 14, adjusting members (set screws) 21, 31, 41 and spring elements 22, 32, 42 associated therewith, a holder 24 (holder holder) for the lens holder, and a bearing housing 27 with the lens holder The lens holder 23, in which the collimator lens 14 is inserted, is pivotably supported in the carrier 24, which in turn is slidably supported in the bearing housing 27 along the longitudinal direction x. Of the
Carrier 24 is composed of two components of disk-like basic shape, namely a front part 25 and a back part 26th
Referring to Figures 2 and 3, the bearing housing 27 has the basic shape of a cup, the bottom of which (Figure 1) faces outwardly and which has a flange 28 with a e.g. parallelepiped formation (Fig. 3) added, preferably integrally formed, is. The bearing housing 27 is placed on the opening of the cup side of a - designated by reference numeral 29 - support surface of the housing of the laser module 10, whereby the bearing housing 27 with the carrier 24 housed therein from the support surface (as by a cover) is closed , By means of the flange 28, the bearing housing 29 can be secured to the support surface 29, e.g. be screwed on the four ends by means of the fastening screws 18a. Through the support surface 29, the above-mentioned radiation opening 15 of the laser unit 11 runs.
The position of the carrier 24 along the direction x is adjusted in the bearing housing 27 by longitudinal adjusting means, which are designed as two adjusting screws 21 in the embodiment shown. The adjusting screws 21 are arranged parallel to the longitudinal direction x and opposite to each other with respect to the position of the laser diode 12. The heads of the adjusting screws 21 are accessible on the outside (Figure 1) of the laser unit, so here e.g. Hex key or other suitable tool can be set to adjust the adjustment screws 21 to a desired position of the longitudinal direction x. The adjusting screws 21 act on the carrier 24, more precisely on the outside of the back part 26 of the carrier 24. The carrier 24 is by rubber springs 22, between him - namely on the end face of the front part 25 (see Fig. 3) - Support surface 29 are arranged, pressed against the adjusting screws 21. Characterized the carrier 24 is biased against the housing, he sttitzt always on the end surfaces of the adjusting screws 21, and a game of the carrier 24 is avoided. The longitudinal adjustment according to the embodiment shown allows a total displacement in the order of about ± 1 mm.
In Fig. 4, the lens holder 23 is shown with the associated adjusting means; the carrier 24 is opened, namely with removed front part 25, so that only the back part 26 is shown.
Referring to Figs. 2 and 4, the lens holder 23 has a central body 30 whose outer shape is that of a ring having spherical-zone-shaped outer surfaces. The collimator lens 14 is inserted into the body 30, namely, in a recess of the body opposite to the side through which the laser light source 12 emits the light toward the lens holder; the lens may be in the recess e.g. be fixed by gluing. The carrier 24 has a hollow spherical cavity into which the body 30 of the lens holder 23 is received, so that the latter is mounted in the carrier 24 in the manner of a ball joint.
In the back part 26, two adjusting means 31, 41 are provided, through which the lens holder 23 - and thus the collimator lens 14 held therein - can be pivoted about a respectively zugeordnete spatial axis which is transverse to the longitudinal direction. In the embodiment shown, each of the two adjusting means is designed as adjusting screw 31, 41, which are arranged parallel to the longitudinal direction eccentrically to the position of the collimator lens 14. The heads of the adjusting screws 31, 41 are guided through the bearing housing 27 and thus accessible on the outside (FIG. 1) of the laser unit, so that the adjusting screws 31, 41 can be adjusted to a desired position by means of a suitable tool.
The adjusting screw 31 is for adjusting the pivotal position of the collimator lens 14 about a first transverse axis, the y-axis; the adjusting screw 41 serves to adjust the pivotal position of the collimator lens 14 about a second transverse axis, the z-axis.
The set screw 31 acts on a jack 33 which extends transversely from the axis of propagation of light from the body 30 of the lens holder 23 and pushes it over a rubber spring 32 against an inner mating surface 34 (Figure 2) in the front part 25 of the carrier 24. This rubber spring is preferably formed as a flat rubber ring, which additionally allows, within the rubber ring (ie in the inner opening) form an elevated stop surface 35, which may preferably be formed obliquely, as a parallel and thus planar stop to the end position of the lever to act, see Fig.2. It is advantageous if the end face of the screw 31 and / or the associated contact surface of the lever 33 is curved, for example, spherically curved; In this way, at the point of contact of these two surfaces results in a defined joint. By the action of the rubber spring 32, the Hebei is biased against the carrier; a match between screw 31 and Hebei 33 avoided.
The set screw 41 acts on a jack 43 which extends from the body 30 of the lens holder 23 in a direction other than the jack 33; the Hebei 33 and 43 are preferably arranged offset from one another by 90 ° about the longitudinal axis. The Hebei 43 is pressed by a rubber spring 42 against the inner counter surface 34. For the rest, what has been said about Hebei 33 applies to Hebei 43 in an analogous way.
The axis of rotation is defined in each case by the extension of the center point of the ball joint to the support point of the adjusting means 31, 41 at the end of the respective associated lever 33, 43 of the lens holder 23. These axes of rotation correspond to the axes y and z of Fig. 4. With the screws 31,41 adjusting the pivot position by a total of ± 1.5 ° is possible. The accuracy is, for example, 0.5 ° per revolution; more preferably 0.1 ° per revolution.
Fig. 5 shows a variant of the lens holder with modified levers 36, 46 and modified body 38 of the lens holder 39. Since the Hebei 36.46 are pivoted in the rotation over the other of the other Hebei 46, 36, these are as shown in FIG. 5 shown advantageously provided with curves 37, 47, which for each position an equal pressure point of the counter surface 34 is applied. In addition, a cylin-derförmiger approach 44 may be formed on the body 38, which is stored according to the (not shown) carrier. Both modifications shown in Fig. 5 allow a more fluid pivot about the two axes of the Hebei 36,46.
The adjustment process of the collimator optics 13 with the aid of the adjusting device 20 according to the invention takes place, for example, as follows. The laser light source 12 is activated and the light spot (laser spot) generated on the target surface (i.e., the above-mentioned programmed pivotable mirror or phosphor conversion element, respectively) is observed. In general, the laser spot is located outside the destination required for the operation in the center of the target area and is also defocused. First, by adjusting the set screws 31 and 41, the position of the laser spot is changed until the laser spot is at the target location, which typically has a dimension of a few millimeters (e.g., 2-3 mm). Then, the collimator optics are displaced in the longitudinal direction x by means of the adjusting screws 21 until the laser spot on the associated target surface is focused as required. For adjustment, for example, a gauge may be used which includes a sensor which is arranged so that it
Destination and thus provides a return value for the setting described above. As part of the assembly, the intended for the destination optical element is then positioned.
If desired, the adjusting means 21, 31, 41 can be permanently detected after adjusting the collimator lens 13, 14 in the set position. This can be done for example by a clamping of the screw head or by applying a thermosetting adhesive around the screw head.
The laser module 10 with the collimator optics 13 thus set can then be inserted into a headlight 9 - shown in FIG. 6 in a partially cutaway view - at the position provided for this purpose.
It should be emphasized that the exemplary embodiment is for the purpose of illustration and is not to be construed restrictively. Thus, e.g. Instead of the screws other suitable devices for mechanical or electro-mechanical adjustment by hand and / or be provided by servomotors. In a variant in which a pivoting of the lens about only one axis is sufficient, instead of a ball-joint-like configuration, a rotary joint can also be used. Also, in other embodiments of the invention, the collimator optics implemented in the embodiment shown above by a (single) lens may be implemented using multiple lenses, one or more mirrors, or a combination of such optical components. Furthermore, the spring elements can be realized as rubber springs or other elastic components, such as e.g. Spiral or leaf springs. In general, numerous modifications and developments are possible within the scope of the invention, which the person skilled in the art can easily find.

权利要求:
Claims (14)
[1]
Patent claims
1. Laser unit (11) for a vehicle headlight with a laser light source (12), preferably a laser diode, a bearing housing (27) in which the laser light source is mounted, and an adjustable collimator (13) for emitted from the laser light source laser light, wherein the collimator at least an optical component (14) which is arranged in a distance to the laser light source running along a longitudinal direction (x), characterized by an adjustment device (20) associated with the collimator optics (13) with a carrier (24) arranged along the longitudinal direction (x ) is adjustable relative to the laser light source (12), wherein the at least one optical component (14) within the carrier (24) about at least one transverse to the longitudinal direction of the spatial axis (y, z) is pivotally mounted.
[2]
2. Laser unit according to claim 1, characterized in that in the bearing housing (27) is provided along the longitudinal direction adjustable longitudinal adjusting device (21), wherein the carrier (24) against the longitudinal adjusting device (21) is supported.
[3]
3. Laser unit according to claim 2, characterized in that the longitudinal adjusting device (21) as a number of parallel to the longitudinal direction (x) extending adjusting screws is formed.
[4]
4. Laser unit according to claim 2 or 3, characterized in that the longitudinal adjusting device (21) is additionally detectable in its longitudinal position.
[5]
5. Laser unit according to one of claims 2 to 4, characterized in that in the bearing housing (27) at least one elastically deformable spring element (22) is provided, with which the carrier (24) against the longitudinal adjusting device (21) is pressed.
[6]
6. Laser unit according to one of the preceding claims, characterized in that the carrier (24) in the bearing housing (27) along the longitudinal direction adjustable, but the laser light source (12) in the bearing housing (27) is fixedly positioned.
[7]
7. Laser unit according to one of the preceding claims, characterized in that the at least one optical component (14) about two spatial axes (y, z) is pivotally mounted, wherein the mutually perpendicular spatial axes perpendicular to the longitudinal direction (x).
[8]
8. Laser unit according to one of the preceding Ansprtiche, characterized in that in the carrier (24) has a holder (23) in which the optical element (14) is held, and at least one on the bracket attacking Hebei (33, 43), preferably two, are provided, wherein at an outer end of the or each lever (33, 43) in the carrier (24) mounted adjusting means (41, 31) is provided, with which the Hebei is adjustable with respect to its pivoting position.
[9]
9. laser unit according to claim 8, characterized in that in each case an elastically deformable spring element (32,42) between a Hebei (33,43) and a counter-surface (34) of the carrier (24) is arranged and the at least one Hebei (33, 43) in each case by an adjusting means (31, 41), preferably an eccentrically extending screw, via the spring element (32,42) against the counter surface (34) is pressed.
[10]
10. A laser unit according to claim 8 or 9, characterized in that the Hebei (33, 43) with the associated adjusting means (31, 41) is connected via a hinge connection, wherein the articulated connection between an end face of the actuating means and a contacting this contact surface of the lever is formed, wherein the end face and / or the contact surface are preferably formed as a spherically curved contact surface.
[11]
11. Laser unit according to one of Ansprtiche 8 to 10, characterized in that the / the adjusting means (31,41) is additionally rotatably fixed / are.
[12]
12. Laser unit according to one of Ansprtiche 8 to 11, characterized in that the holder (23) and the at least one Hebei (33,43) are formed einstiickig each other.
[13]
13. Laser module (10) comprising a plurality of laser units (11) according to one of the preceding Ansprtiche.
[14]
14. Vehicle headlight (9) with a laser unit (11) and / or a laser module (10) according to one of the preceding Ansprtiche.

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法律状态:
2022-02-15| MM01| Lapse because of not paying annual fees|Effective date: 20210619 |

优先权:

申请号 | 申请日 | 专利标题

ATA50517/2015A|AT517407B1|2015-06-19|2015-06-19|Laser unit with collimator adjustment device|ATA50517/2015A| AT517407B1|2015-06-19|2015-06-19|Laser unit with collimator adjustment device|

JP2017565711A| JP2018521352A|2015-06-19|2016-05-27|Laser unit having collimator adjustment device|

EP16728600.4A| EP3311211B1|2015-06-19|2016-05-27|Laser unit having a collimator adjusting device|

PCT/AT2016/050166| WO2016201464A1|2015-06-19|2016-05-27|Laser unit having a collimator adjusting device|

US15/737,461| US10274154B2|2015-06-19|2016-05-27|Laser unit having a collimator adjusting device|

CN201680034636.5A| CN107743593B|2015-06-19|2016-05-27|Laser unit, laser module and vehicle headlight|

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